A system for receiving feedback in a flight plan of a vehicle includes a haptic-enabled device comprising a crew seat with an inceptor mounted thereto; and a processor with memory having instructions stored thereon that, when executed by the processor, cause the system to: receive signals indicative of the flight plan for the vehicle; receive deviation signals indicative of a proposed deviation in a trajectory for the flight plan; and transmit signals to the haptic-enabled device representing trajectory constraints in the proposed deviation in response to the receiving of the deviation signals.

A system may include a display and a processor communicatively coupled to the display. The processor may be configured to: output, to the display, a synthetic vision system (SVS) taxi mode exocentric view of an aircraft while the aircraft is performing taxi operations, while the aircraft is on ground, and when the aircraft is not in a predetermined exclusion zone, the predetermined exclusion zone including portions of a runway where the aircraft is able to begin taking off; and output, to the at least one display, an SVS flight mode egocentric view from the aircraft when the aircraft is in the predetermined exclusion zone. The display may be configured to display the SVS taxi mode exocentric view until the aircraft is in the predetermined exclusion zone and display the SVS flight mode egocentric view when the aircraft is in the predetermined exclusion zone.

One embodiment is a navigation system for an aircraft including a positioning system to generate information related to a position of the aircraft, a group of cameras mounted to a body of the aircraft, each camera of the group of cameras to simultaneously capture images of a portion of an environment that surrounds the aircraft, and a processing component coupled to the positioning system and the group of cameras, the processing component to determine a current position of the aircraft based on the information related to the position of the aircraft and the images.

Methods and systems for calibrating aircraft position by providing touch-enabled selection of onboard sensors on an aircraft. The method includes receiving sensor map location information for onboard sensors including N position computers, a global positioning system (GPS) sensor, an inertial reference system (IRS) sensor, and a radio navigation (NAV) sensor; receiving sensor data from the onboard sensors, and configuring a user interface layout for the touch display unit presenting the onboard sensors using symbols at respective locations. Embodiments depict the sensors with intuitive symbols and provide a terrain layout in the background. The method includes interpreting a touch input from the touch-enabled display unit to select a position computer and an onboard sensor, and to calibrate the selected position computer with the selected onboard sensor and update the user interface layout to reflect the calibration, responsive to the touch input.

A flight management assembly including two guidance systems, each one provided with a flight management system. The flight management systems are independent and hosted in different computer equipment. Each of the flight management systems being configured to carry out at least a computation of guidance commands for the aircraft. The flight management assembly also includes a monitoring unit hosted in computer equipment different from the computer equipment hosting the flight management systems and configured to monitor at least the guidance commands computed by the two flight management systems to detect and identify a defective flight management system.

An aircraft mission computing system includes an aircraft mission path computing engine, and a mission deck comprising a display and a display management assembly configured for displaying, on the display, at least one button for defining an operational specification of the mission. The computing engine is configured to be activated after defining the choice of operational specification using the definition button to determine at least one possible path of the aircraft based on the or each choice of defined operational specification using the or each definition button. The display management assembly is configured to display, on the display, after the activation of the computing engine, at least one outcome indicator providing mission feasibility information while respecting the or each operational specification choice.

To bring an aircraft in flight to a runway, an automatic trajectory generation system obtains a procedure, called STARI procedure, which provides a final trajectory flyable by the aircraft to land on the runway, such that from the entry point of the final trajectory or from any point above it, a holding loop pattern of a predefined shape is flyable in order to dissipate energy if necessary. The automatic trajectory generation system then computes a lateral trajectory, avoiding any terrain relief, meteorological obstacles and military zones, between the current position of the aircraft and the entry point or a point above it, based on performance adapted to an operational state of the aircraft. An overall trajectory is thus obtained, by linking the computed lateral trajectory and the final trajectory of the STARI procedure, including iterations of the holding loop pattern if necessary.

A display system for an aircraft includes a processing unit and a display device. The processing unit is configured to receive data representative of a landing platform on a movable carrier, and the data includes current energy parameters of the movable carrier. The processing unit is further configured to generate display commands associated with the landing platform and the energy parameters of the movable carrier. The display device is coupled the processing unit for receiving the display commands and operable to render first symbology representing the landing platform and second symbology representing the energy parameters of the movable carrier.

The invention described herein provides a flight crew with an easier, more intuitive, system and method to create a flight plan. A flight planning system is presented for navigation of an aircraft utilizing a touch screen display device mounted in an aircraft cockpit spanning the width and height of the instrument panel. The system provides navigational views, an interactive map, charts, a radio frequency component, a weather component, and a virtual flight plan. A flight planning method is presented that uses an interactive map on a touch screen device in an aircraft cockpit. The method accepts user inputs and displays a desired flight plan on the map. A method for providing a chart on a touch screen device is presented that includes presenting a list of menu options on a touch screen mounted in an aircraft cockpit. The method provides the flight crew with heads-up operation, providing greater situational awareness.

System and methods for providing situational awareness information to an aircrew of an aircraft including projecting into space, from a grid generator at the landing zone, a set of lines defining a relative navigation grid and encoded with grid data and configured to identify predetermined points on the relative navigation grid that provide situational awareness, detecting, with a detector module on the aircraft, a location of the aircraft within the grid and generating and displaying situational awareness information based on detected location.